A composite light blocking sheet includes a first surface layer, a second surface layer, an inside substrate layer and a central axis. The first surface layer has a first opening and a first outer surface connected to the first opening. The second surface layer has a second opening and a second outer surface connected to the second opening. The inside substrate layer has a substrate opening and is disposed between the first surface layer and the second surface layer and connects the first surface layer and the second surface layer. The central axis is coaxial with the first opening, the second opening and the substrate opening. More than 95% of the first outer surface has a first gloss being gu1, more than 95% of the second outer surface has a second gloss being gu2, and the first gloss gu1 and the second gloss gu2 satisfy specific conditions.
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14. A composite light blocking sheet, comprising:
a first surface layer having a first opening and a first outer surface connected to the first opening;
a second surface layer having a second opening and a second outer surface connected to the second opening, wherein the second opening is disposed corresponding to the first opening;
an inside substrate layer disposed between the first surface layer and the second surface layer and connecting the first surface layer and the second surface layer, wherein the inside substrate layer has a substrate opening corresponding to the first opening and the second opening; and
a central axis being coaxial with the first opening, the second opening and the substrate opening;
wherein more than 95% of the first outer surface has a first gloss being gu1, more than 95% of the second outer surface has a second gloss being gu2, the first gloss gu1 is different from the second gloss gu2, each of the first gloss gu1 and the second gloss gu2 is determined by projecting a beam of a light source at 60 degrees onto each of the first outer surface and the second outer surface when assuming that a vertical direction with respect to each of the first outer surface and the second outer surface is 0 degrees, and the following condition is satisfied:
2.0<GU2/GU1<18.0. 1. A composite light blocking sheet, comprising:
a first surface layer having a first opening and a first outer surface connected to the first opening;
a second surface layer having a second opening and a second outer surface connected to the second opening, wherein the second opening is disposed corresponding to the first opening;
an inside substrate layer disposed between the first surface layer and the second surface layer and connecting the first surface layer and the second surface layer, wherein the inside substrate layer has a substrate opening corresponding to the first opening and the second opening; and
a central axis being coaxial with the first opening, the second opening and the substrate opening;
wherein more than 95% of the first outer surface has a first gloss being gu1, more than 95% of the second outer surface has a second gloss being gu2, the first gloss gu1 is different from the second gloss gu2, each of the first gloss gu1 and the second gloss gu2 is determined by projecting a beam of a light source at 60 degrees onto each of the first outer surface and the second outer surface when assuming that a vertical direction with respect to each of the first outer surface and the second outer surface is 0 degrees, and the following conditions are satisfied:
0%<GU1<1.8%; and 2.0%<GU2<9.0%. 2. The composite light blocking sheet of
3. The composite light blocking sheet of
5 μm<t<50 μm. 4. The composite light blocking sheet of
0.16<d/t<0.81. 5. An imaging lens assembly, comprising:
a barrel;
an optical lens set; and
the composite light blocking sheet of
wherein the optical lens set and the composite light blocking sheet are disposed in the barrel.
6. The imaging lens assembly of
wherein the composite light blocking sheet is disposed between the two lens elements, and an outer diameter of the composite light blocking sheet is smaller than or equal to a minimum inner diameter of the axial connecting surface of each of the two lens elements.
7. The imaging lens assembly of
8. The imaging lens assembly of
0 degrees<θ<40 degrees. 9. The imaging lens assembly of
10. The imaging lens assembly of
1<1000*t/Φ<50. 11. The imaging lens assembly of
12. The imaging lens assembly of
0.30<f/phi D<3.2. 13. An electronic device, comprising:
the imaging lens assembly of
an image sensor, wherein the image sensor is disposed on an image surface of the imaging lens assembly.
15. The composite light blocking sheet of
16. The composite light blocking sheet of
0%<GU1<1.8%; and 2.0%<GU2<9.0%. 17. An imaging lens assembly, comprising:
a barrel;
an optical lens set; and
the composite light blocking sheet of
wherein the optical lens set and the composite light blocking sheet are disposed in the barrel.
18. The imaging lens assembly of
19. The imaging lens assembly of
20. The imaging lens assembly of
21. The imaging lens assembly of
1<1000t/Φ<50. 22. The imaging lens assembly of
0.5<CT/t<35.0. 23. The imaging lens assembly of
2.0<CT/t<25.0. 24. The imaging lens assembly of
wherein the composite light blocking sheet is disposed between the two lens elements, and an outer diameter of the composite light blocking sheet is smaller than or equal to a minimum inner diameter of each of the axial connecting surfaces.
25. An electronic device, comprising:
the imaging lens assembly of
an image sensor, wherein the image sensor is disposed on an image surface of the imaging lens assembly.
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This application claims priority to U.S. Provisional Application Ser. No. 62/422,123, filed Nov. 15, 2016, which is herein incorporated by reference.
The present disclosure relates to a composite light blocking sheet, an imaging lens assembly and an electronic device. More particularly, the present disclosure relates to a composite light blocking sheet for preventing an incorrect assembling which is applicable to an imaging lens assembly and an electronic device.
Recently, the portable devices, such as smart phone and pad, are developed rapidly and ubiquitous in the human life. The imaging lens assembly disposed therein is thus becomes growth industry. With the improvement of the technology, more and more demands for high qualities of imaging lens assembly come out. Therefore, in addition to improving the quality of imaging lens assembly in optical design field, the precision of manufacturing and assembling processes are needed to be improved too.
According to conventional imaging lens assemblies, a light blocking sheet is used to block unnecessary lights therein. The surface properties of the light blocking sheet are critical to the effect of suppressing stray lights. Accordingly, the surface properties of the light blocking sheet affect the image quality of the imaging lens assembly.
A structure of the conventional light blocking sheet can refer to
To sum up, how to improve the ability for identifying the correct side of the light blocking sheet so as to eliminate stray lights effectively has become one of the most important issues nowadays.
According to one aspect of the present disclosure, a composite light blocking sheet includes a first surface layer, a second surface layer, an inside substrate layer and a central axis. The first surface layer has a first opening and a first outer surface connected to the first opening. The second surface layer has a second opening and a second outer surface connected to the second opening. The second opening is disposed corresponding to the first opening. The inside substrate layer is disposed between the first surface layer and the second surface layer and connects the first surface layer and the second surface layer. In addition, the inside substrate layer has a substrate opening corresponding to the first opening and the second opening. The central axis is coaxial with the first opening, the second opening and the substrate opening. More than 95% of the first outer surface has a first gloss being GU1, more than 95% of the second outer surface has a second gloss being GU2, the first gloss GU1 is different from the second gloss GU2, and the following conditions can be satisfied: 0%<GU1<1.8% and 2.0%<GU2<9.0%.
According to another aspect of the present disclosure, an imaging lens assembly can include a barrel, an optical lens set and the composite light blocking sheet as mentioned above. The optical lens set and the composite light blocking sheet can be disposed in the barrel.
According to yet another aspect of the present disclosure, an electronic device can include the abovementioned imaging lens assembly and an image sensor. The image sensor can be disposed on an image surface of the imaging lens assembly.
According to further another aspect of the present disclosure, a composite light blocking sheet includes a first surface layer, a second surface layer, an inside substrate layer and a central axis. The first surface layer has a first opening and a first outer surface connected to the first opening. The second surface layer has a second opening and a second outer surface connected to the second opening. The second opening is disposed corresponding to the first opening. The inside substrate layer is disposed between the first surface layer and the second surface layer and connects the first surface layer and the second surface layer. In addition, the inside substrate layer has a substrate opening corresponding to the first opening and the second opening. The central axis is coaxial with the first opening, the second opening and the substrate opening. More than 95% of the first outer surface has a first gloss being GU1, more than 95% of the second outer surface has a second gloss being GU2, the first gloss GU1 is different from the second gloss GU2, and the following condition can be satisfied: 2.0<GU2/GU1<18.0.
According to still another aspect of the present disclosure, an imaging lens assembly can include a barrel, an optical lens set and the composite light blocking sheet as mentioned above. The optical lens set and the composite light blocking sheet can be disposed in the barrel.
According to yet another aspect of the present disclosure, an electronic device can include the abovementioned imaging lens assembly and an image sensor. The image sensor can be disposed on an image surface of the imaging lens assembly.
The present disclosure can be more fully understood by reading the following detailed description of the embodiment, with reference made to the accompanying drawings as follows:
Please refer to
In the meanwhile, please refer to
In
In particular, the first surface layer 110 can include a first outer surface 112 and a first inner surface 113 which are both connected to the first opening 111. The second surface layer 120 can include a second outer surface 122 and a second inner surface 123 which are both connected to the second opening 121. The first surface layer 110 can be connected to the inside substrate layer 130 via the first inner surface 113, and the second surface layer 120 can be connected to the inside substrate layer 130 via the second inner surface 123.
The inside substrate layer 130 can be made of a plastic material, and each of the first surface layer 110 and the second surface layer 120 can be made of a black carbon-containing material. Therefore, the composite light blocking sheet 100 can be made of the composite material, which is favorable for enhancing strength of the material, reducing the thickness of the composite light blocking sheet 100, and Improving uniformity and smoothness of the entire composite light blocking sheet 100. Specifically, the plastic material of the inside substrate layer 130 can be black or transparent polycarbonate (PC), polyethylene terephthalate (PET), polymethylmethacrylate (PMMA) or a combination thereof.
After measuring, the gloss of the specific position P on the first outer surface 112 of the first surface layer 110 is obtained. Glosses of other positions on the first outer surface 112 can be determined in turn. Similarly, glosses on the second outer surface 122 can be obtained by the same instrument and method as mentioned above. In the present disclosure, most area of the first outer surface 112 has a first gloss, most area of the second outer surface 122 has a second gloss, and the first gloss is different from the second gloss. More particularly, according to the embodiment of
When a thickness of the composite light blocking sheet 100 is t, the following condition can be satisfied: 5 μm<t<50 μm. Thus, the excessive thickness tolerance can be avoided by arranging the proper thickness of the composite light blocking sheet 100. Accordingly, the accumulated spacing tolerance in assembling can be further reduced.
When a thickness of the inside substrate layer 130 is d, and the thickness of the composite light blocking sheet 100 is t, the following condition can be satisfied: 0.16<d/t<0.81. Compared to the first surface layer 110 or the second surface layer 120, the inside substrate layer 130 usually reflects the intense light easily. Thus, the composite light blocking sheet 100 which satisfies the above condition is a thinner light blocking sheet so that less of the inside substrate layer 130 will be exposed to reflect the intense light.
When a maximum outer diameter of the composite light blocking sheet 100 is ϕ, and the thickness of the composite light blocking sheet 100 is t, the following condition can be satisfied: 1<1000 t/ϕ<50. Preferably, when the maximum outer diameter of the composite light blocking sheet 100 is ϕ, and the thickness of the composite light blocking sheet 100 is t, the following condition can be satisfied: 1<1000 t/ϕ<25. Accordingly, a larger and thinner light blocking range can be provided. Moreover, a firm and thinner light blocking sheet also can be provided by the abovementioned composite material.
A thickness of each of the inside substrate layer 130, the first surface layer 110 and the second surface layer 120 can be uniform. Therefore, the fast and mass production can be achieved. The raw material can be supplied in the form of material band, which is favorable for the subsequent processing. “The thickness can be uniform” refers that the thickness is identical. That is, the thickness of the inside substrate layer 130 parallel to the central axis Z is identical except the substrate opening 131; the thickness of the first surface layer 110 parallel to the central axis Z is identical except the first opening 111; the thickness of the second surface layer 120 parallel to the central axis Z is identical except the second opening 121.
As mentioned above, the orientation of the light blocking sheet 1 cannot be identified when the gloss of the first surface layer L1 is the same as the gloss of the second surface layer L2 in the conventional light blocking sheet 1. Accordingly, a gloss of the first surface layer 110 and a gloss of the second surface layer 120 in the present disclosure are designed to overcome problems existed in the conventional light blocking sheet 1.
Please refer to
Specifically, the imaging lens assembly 1000 further includes an object-side end 1300, an image-side end 1400 and an image surface 1500. The object-side end 1300 faces an imaged object (not shown), and the image-side end 1400 faces the image surface 1500. The optical lens set 1200 includes at least two lens elements (1210, 1220, 1230, 1240, 1250, 1260), and the composite light blocking sheet 100 is adjacent to at least one of the lens elements (1210, 1220, 1230, 1240, 1250, and 1260). Other spacing elements (1610, 1620, 1630, and 1640) can be disposed between two of the lens elements (1210, 1220, 1230, 1240, 1250, and 1260).
More specifically, the optical lens set 1200 includes a first lens element 1210, a second lens element 1220, a third lens element 1230, a fourth lens element 1240, a fifth lens element 1250 and a sixth lens element 1260. A spacing element 1610 is disposed between the first lens element 1210 and the second lens element 1220. A spacing element 1620 is disposed between the second lens element. 1220 and the third lens element 1230. A spacing element 1630 is disposed between the fourth lens element 1240 and the fifth lens element 1250. A spacing element 1640 is disposed between the fifth lens element 1250 and the sixth lens element 1260. It is noted that the spacing element 1610, the spacing element 1620, the spacing element 1630 and/or the spacing element 1640 can be replaced by the composite light blocking sheet 100.
In
In addition, as shown in a partial enlarged diagram in
When a diameter of the substrate opening 131 is phi D, and a focal length of the imaging lens assembly 1000 is f, the following condition can be satisfied: 0.30<f/phi D<3.2. Preferably, when the diameter of the substrate opening 131 is phi D, and the focal length of the imaging lens assembly 1000 is f, the following condition can be satisfied: 0.50<f/phi D<2.2. Therefore, the composite light blocking sheet 100 is appropriate for an imaging lens assembly with demands of large amount of light that can reach an image surface.
When a distance on the central axis Z between the two lens elements, where the composite light blocking sheet 100 is disposed therebetween, is CT, and the thickness of the composite light blocking sheet 100 is t, the following condition can be satisfied: 0.5<CT/t<35.0. Therefore, an ideal light blocking effect is achieved in a compact lens structure. Preferably, when the distance on the central axis Z between the two lens elements, where the composite light blocking sheet 100 is disposed therebetween, is CT, and the thickness of the composite light blocking sheet 100 is t, the following condition can be further satisfied: 2.0<CT/t<25.0. Accordingly, the composite light blocking sheet 100 of the present disclosure Is favorable to be applied in a high image quality imaging lens assembly that can include a plurality of lens elements (at least five lens elements). In order to reduce the stray lights in the imaging lens assembly 1000 under the intense light, more surface of the composite light blocking sheet 100 having a lower gloss can be designed to improve the image quality.
The composite light blocking sheet 100 can not only be applied for blocking light but also can be an aperture stop of the imaging lens assembly 1000. Therefore, the structure of the imaging lens assembly 1000 can be simplified. Moreover, the composite light blocking sheet 100 has a lower gloss so that unexpected stray lights can be avoided so as to be a more accurate optical element.
The details of the composite light blocking sheet 100, such as the thickness of the composite light blocking sheet 100, the thickness of the inside substrate layer 130, the diameter of the substrate opening 131 and the glosses of the first outer surface 112 and the second outer surface 122, are illustrated as above, and there is no further description herein.
Please refer to
In particular, the first surface layer 110a includes a first outer surface 112a and a first inner surface 113a which are both connected to the first opening 111a. The second surface layer 120a includes a second outer surface 122a and a second inner surface 123a which are both connected to the second opening 121a. The first surface layer 110a is connected to the inside substrate layer 130a via the first inner surface 113a, and the second surface layer 120a is connected to the inside substrate layer 130a via the second inner surface 123a. Moreover, more than 95% of the first outer surface 112a has a first gloss being GU1, and more than 95% of the second outer surface 122a has a second gloss being GU2, wherein the first gloss GU1 is different from the second gloss GU2.
In the composite light blocking sheet 100a according to the 1st example, a thickness of the inside substrate layer 130a is d, a thickness of the composite light blocking sheet 100a is t, a maximum outer diameter of the composite light blocking sheet 100a is ϕ, and a diameter of the substrate opening 131a is phi D. The values of d, t, d/t, ϕ, 1000 t/ϕ, phi D, GU1, GU2, and GU2/GU1 of the 1st example are listed in Table 1.
TABLE 1
1st Example
d (mm)
0.013
phi D
1.7
t (mm)
0.023
GU1 (%)
0.6
d/t
0.565
GU2 (%)
8
Φ (mm)
3.25
GU2/GU1
13.33
1000 t/Φ
7.077
In particular, the first surface layer 110b includes a first outer surface 112b and a first inner surface 113b which are both connected to the first opening 111b. The second surface layer 120b includes a second outer surface 122b and a second inner surface 123b which are both connected to the second opening 121b. The first surface layer 110b is connected to the inside substrate layer 130b via the first inner surface 113b, and the second surface layer 120b is connected to the inside substrate layer 130b via the second inner surface 123b. Moreover, more than 95% of the first outer surface 112b has a first gloss being GU1, and more than 95% of the second outer surface 122b has a second gloss being GU2, wherein the first gloss GU is different from the second gloss GU2.
In the 2nd example, the definitions of these parameters as shown in the following Table 2 are the same as those stated in the 1st example with corresponding values for the 2nd example, so an explanation in this regard will not be provided again.
TABLE 2
2nd Example
d (mm)
0.032
phi D
2.5
t (mm)
0.041
GU1 (%)
0.4
d/t
0.780
GU2 (%)
3
Φ (mm)
3.55
GU2/GU1
7.5
1000 t/Φ
11.549
In particular, the first surface layer 110c includes a first outer surface 112c and a first inner surface 113c which are both connected to the first opening 111c. The second surface layer 120c includes a second outer surface 122c and a second inner surface 123c which are both connected to the second opening 121c. The first surface layer 110c is connected to the inside substrate layer 130c via the first inner surface 113c, and the second surface layer 120c is connected to the inside substrate layer 130c via the second inner surface 123c. Moreover, more than 95% of the first outer surface 112c has a first gloss being GU1, and more than 95% of the second outer surface 122c has a second gloss being GU2, wherein the first gloss GU1 is different from the second gloss GU2.
In the 3rd example, the definitions of these parameters as shown in the following Table 3 are the same as those stated in the 1st example with corresponding values for the 3rd example, so an explanation in this regard will not be provided again.
TABLE 3
3rd Example
d (mm)
0.013
phi D
3.48
t (mm)
0.023
GU1 (%)
1.2
d/t
0.565
GU2 (%)
5.4
Φ (mm)
4.24
GU2/GU1
4.5
1000 t/Φ
5.425
In particular, the first surface layer 110d includes a first outer surface 112d and a first inner surface 113d which are both connected to the first opening 111d. The second surface layer 120d includes a second outer surface 122d and a second inner surface 123d which are both connected to the second opening 121d. The first surface layer 110d is connected to the inside substrate layer 130d via the first inner surface 113d, and the second surface layer 120d is connected to the inside substrate layer 130d via the second inner surface 123d. Moreover, more than 95% of the first outer surface 112d has a first gloss being GU1, and more than 95% of the second outer surface 122d has a second gloss being GU2, wherein the first gloss GU1 is different from the second gloss GU2.
In the 4th example, the definitions of these parameters as shown in the following Table 4 are the same as those stated in the 1st example with corresponding values for the 4th example. In some situations, it should be noted that an orientation of the second gloss GU2 with a lower value than the first gloss GU1 toward a different direction from previously mentioned examples can help reduce an unexpected surface reflection.
TABLE 4
4th Example
d (mm)
0.013
phi D
2.84
t (mm)
0.023
GU1 (%)
7.6
d/t
0.565
GU2 (%)
0.9
Φ (mm)
3.98
GU2/GU1
0.118
1000 t/Φ
5.779
In the 5th example, a portion of the second surface layer 120e near the second opening 121e bends towards the inside substrate layer 130e and the first surface layer 110e. That is, the composite light blocking sheet 100e is not a flat sheet. Moreover, a diameter of the second opening 121e is smaller than a diameter of the substrate opening 131e, and the diameter of the substrate opening 131e is smaller than a diameter of the first opening 111e. That is, the inner surface of the first opening 111e, the substrate opening 131e and the second opening 121e is a conical surface.
In particular, the first surface layer 110e includes a first outer surface 112e and a first inner surface 113e which are both connected to the first opening 111e. The second surface layer 120e includes a second outer surface 122e and a second inner surface 123e which are both connected to the second opening 121e. The first surface layer 110e is connected to the inside substrate layer 130e via the first inner surface 113e, and the second surface layer 120e is connected to the inside substrate layer 130e via the second inner surface 123e. Moreover, more than 95% of the first outer surface 112e has a first gloss being GU1, and more than 95% of the second outer surface 122e has a second gloss being GU2, wherein the first gloss GU1 is different from the second gloss GU2.
In the 5th example, the definitions of these parameters as shown in the following Table 5 are the same as those stated in the 1st example with corresponding values for the 5th example, so an explanation in this regard will not be provided again.
TABLE 5
5th Example
d (mm)
0.014
phi D
2.28
t (mm)
0.024
GU1 (%)
0.8
d/t
0.583
GU2 (%)
3.8
Φ (mm)
4.45
GU2/GU1
4.75
1000 t/Φ
5.393
In particular, the first surface layer 110f includes a first outer surface 112f and a first inner surface 113f which are both connected to the first opening 111f. The second surface layer 120f includes a second outer surface 122f and a second inner surface 123f which are both connected to the second opening 121f. The first surface layer 110f is connected to the inside substrate layer 130f via the first inner surface 113f, and the second surface layer 120f is connected to the inside substrate layer 130f via the second inner surface 123f. Moreover, more than 95% of the first outer surface 112f has a first gloss being GU1, and more than 95% of the second outer surface 122f has a second gloss being GU2, wherein the first gloss GU1 is different from the second gloss GU2.
In the 6th example, the definitions of these parameters as shown in the following Table 6 are the same as those stated in the 1st example with corresponding values for the 6th example, so an explanation in this regard will not be provided again.
TABLE 6
6th Example
d (mm)
0.013
phi D
3.83
t (mm)
0.023
GU1 (%)
0.9
d/t
0.565
GU2 (%)
6.8
Φ (mm)
5.45
GU2/GU1
7.56
1000 t/Φ
4.22
In particular, the first surface layer 110g includes a first outer surface 112g and a first inner surface 113g which are both connected to the first opening 111g. The second surface layer 120g includes a second outer surface 122g and a second inner surface 123g which are both connected to the second opening 121g. The first surface layer 110g is connected to the inside substrate layer 130g via the first inner surface 113g, and the second surface layer 120g is connected to the inside substrate layer 130g via the second inner surface 123g. Moreover, more than 95% of the first outer surface 112g has a first gloss being GU1, and more than 95% of the second outer surface 122g has a second gloss GU2, wherein the first gloss GU1 is different from the second gloss GU2.
In the 7th example, the definitions of these parameters as shown in the following Table 7 are the same as those stated in the 1st example with corresponding values for the 7th example, so an explanation in this regard will not be provided again.
TABLE 7
7th Example
d (mm)
0.006
phi D
1.7
t (mm)
0.016
GU1 (%)
0.3
d/t
0.375
GU2 (%)
3.2
Φ (mm)
3.25
GU2/GU1
10.67
1000 t/Φ
4.923
In particular, the first surface layer 110h includes a first outer surface 112h and a first inner surface 113h which are both connected to the first opening 111h. The second surface layer 120h includes a second outer surface 122h and a second inner surface 123h which are both connected to the second opening 121h. The first surface layer 110h is connected to the inside substrate layer 130h via the first inner surface 113h, and the second surface layer 120h is connected to the inside substrate layer 130h via the second inner surface 123h. Moreover, more than 95% of the first outer surface 112h has a first gloss being GU1, and more than 95% of the second outer surface 122h has a second gloss being GU2, wherein the first gloss GU1 is different from the second gloss GU2.
In the 8th example, the definitions of these parameters as shown in the following Table 8 are the same as those stated in the 1st example with corresponding values for the 8th example, so an explanation in this regard will not be provided again.
TABLE 8
8th Example
d (mm)
0.028
phi D
2.5
t (mm)
0.037
GU1 (%)
0.7
d/t
0.757
GU2 (%)
3.4
Φ (mm)
3.55
GU2/GU1
4.86
1000 t/Φ
10.423
Specifically, the imaging lens assembly 3000 further includes an object-side end 3300, an image-side end 3400 and an image surface 3500. The object-side end 3300 faces an imaged object (not shown), and the image-side end 3400 faces the image surface 3500. More specifically, the optical lens set 3200 includes a first lens element 3210, a second lens element 3220, a third lens element 3230, a fourth lens element 3240, a fifth lens element 3250 and a sixth lens element 3260.
The composite light blocking sheet 100a is disposed between the second lens element 3220 and the third lens element 3230, and the composite light blocking sheet 100b is disposed between the third lens element 3230 and the fourth lens element 3240. A spacing element 3610 is disposed between the first lens element 3210 and the second lens element 3220. A spacing element 3620 is disposed between the fourth lens element 3240 and the fifth lens element 3250. A spacing element 3630 is disposed between the fifth lens element 3250 and the sixth lens element 3260.
The first outer surface 112a of the first surface layer 110a of the composite light blocking sheet 100a faces towards the object-side end 3300 of the imaging lens assembly 3000. The first outer surface 112b of the first surface layer 110b of the composite light blocking sheet 100b also faces towards the object-side end 3300 of the imaging lens assembly 3000. Therefore, the reflection of the stray lights can be reduced by correcting assembling the composite light blocking sheet 100a and the composite light blocking sheet 100b. Moreover, the assembling process of the imaging lens assembly 3000 can be simplified by unifiedly using the outer surfaces which has a lower gloss to face towards the object-side end 3300.
In the imaging lens assembly 3000 according to the 9th example, the parameters of the composite light blocking sheet 10a and the composite light blocking sheet 100b, such as d, t, d/t, ϕ, 1000 t/ϕ, phi D, GU1, GU2, and GU2/GU1, a distance on the central axis Z between the second lens element 3220 and the third lens element 3230 is CT1, a distance on the central axis Z between the third lens element 3230 and the fourth lens element 3240 is CT2, and a focal length of the imaging lens assembly 3000 is f. The values of d, t, d/t, ϕ, 1000 t/ϕ, phi D, f, f/phi D, CT1, CT2, CT1/t, CT2/t, GU1, GU2, and GU2/GU1 of the 9th example are listed in Table 9.
TABLE 9
9th Example
f = 3.952 mm
Composite light blocking sheet 100a
d (mm)
0.013
f/phi D
2.32
t (mm)
0.023
CT1 (mm)
0.351
d/t
0.565
CT1/t
15.26
Φ (mm)
3.25
GU1 (%)
0.6
1000 t/Φ
7.077
GU2 (%)
8
phi D
1.7
GU2/GU1
13.33
Composite light blocking sheet 100b
d (mm)
0.032
f/phi D
1.58
t (mm)
0.041
CT2 (mm)
0.157
d/t
0.780
CT2/t
3.829
Φ (mm)
3.55
GU1 (%)
0.4
1000 t/Φ
11.549
GU2 (%)
3
phi D
2.5
GU2/GU1
7.5
Specifically, the imaging lens assembly 4000 further includes an object-side end 4300, an image-side end 4400, and an image surface 4500. The object-side end 4300 faces an imaged object (not shown), and the image-side end 4400 faces the image surface 4500. More specifically, the optical lens set 4200 includes a first lens element 4210, a second lens element 4220, a third lens element 4230, a fourth lens element 4240, and a fifth lens element 4250.
The composite light blocking sheet 100c is disposed between the first lens element 4210 and the second lens element 4220, and the composite light blocking sheet 100d is disposed between the fourth lens element 4240 and the fifth lens element 4250. A spacing element 4610 is disposed between the second lens element 4220 and the third lens element 4230. A spacing element 4620 is disposed between the fourth lens element 4240 and the fifth lens element 4250.
The first outer surface 112c of the first surface layer 110c of the composite light blocking sheet 100c faces towards the object-side end 4300 of the imaging lens assembly 4000. The first outer surface 112d of the first surface layer 110d of the composite light blocking sheet 100d also faces towards the object-side end 4300 of the imaging lens assembly 4000. Therefore, the reflection of the stray lights can be reduced by correcting assembling the composite light blocking sheet 100c and the composite light blocking sheet 100d.
In the 10th example, the composite light blocking sheet 100c is not only applied for blocking light but also an aperture stop of the imaging lens assembly 4000. Therefore, the structure of the imaging lens assembly 4000 can be simplified. Moreover, the imaging lens assembly 4000 further includes a glass panel 4700, which is disposed between the image-side end 4400 and the image surface 4500. The glass panel 4700 can be cover glass, filter or both above, and will not affect a focal length of the imaging lens assembly 4000.
In the imaging lens assembly 4000 according to the 10th example, the parameters of the composite light blocking sheet 100c and the composite light blocking sheet 100d, such as d, t, d/t, Φ, 1000 t/Φ, phi D, GU1, GU2, and GU2/GU1, a distance on the central axis Z between the first lens element 4210 and the second lens element 4220 is CT1, a distance on the central axis Z between the fourth lens element 4240 and the fifth lens element 4250 is CT2, and the focal length of the imaging lens assembly 4000 is f. The values of d, t, d/t, Φ, 1000 t/Φ, phi D, f, f/phi D, CT1, CT2, CT1/t, CT2/t, GU1, GU2, and GU2/GU1 of the 10th example are listed in Table 10. It is clearly disclosed that the second gloss GU2 of the composite light blocking sheet 100d is facing the glass panel 4700 while the first gloss GU1 with a higher value than the second gloss GU2 of the composite light blocking sheet 100d is facing the object-side end 4300 of the imaging lens assembly 4000. In other words, the second surface layer 120d (shown in
TABLE 10
10th Example
f = 10.686 mm
Composite light blocking sheet 100c
d (mm)
0.013
f/phi D
3.07
t (mm)
0.023
CT1 (mm)
0.114
d/t
0.565
CT1/t
4.957
Φ (mm)
4.24
GU1 (%)
1.2
1000 t/Φ
5.425
GU2 (%)
5.4
phi D
3.48
GU2/GU1
4.5
Composite light blocking sheet 100d
d (mm)
0.013
f/phi D
3.763
t (mm)
0.023
CT2 (mm)
0.529
d/t
0.565
CT2/t
23
Φ (mm)
3.98
GU1 (%)
7.6
1000 t/Φ
5.779
GU2 (%)
0.9
phi D
2.84
GU2/GU1
0.118
Specifically, the imaging lens assembly 5000 further includes an object-side end 5300, an image-side end 5400, and an image surface 5500. The object-side end 5300 faces an imaged object (not shown), and the image-side end 5400 faces the image surface 5500. More specifically, the optical lens set 5200 includes a first lens element 5210, a second lens element 5220, a third lens element 5230, a fourth lens element 5240, and a fifth lens element 5250.
The composite light blocking sheet 100e is disposed between the third lens element 5230 and the fourth lens element 5240, and the composite light blocking sheet 100f is disposed between the fourth lens element 5240 and the fifth lens element 5250. A spacing element 5610 is disposed between the first lens element 5210 and the second lens element 5220. A spacing element 5620 is disposed between the second lens element 5220 and the third lens element 5230.
The first outer surface 112e of the first surface layer 110e of the composite light blocking sheet 100e faces towards the object-side end 5300 of the imaging lens assembly 5000. The first outer surface 112f of the first surface layer 110f of the composite light blocking sheet 100f also faces towards the object-side end 5300 of the imaging lens assembly 5000. Therefore, the reflection of the stray lights can be reduced by correcting assembling the composite light blocking sheet 100e and the composite light blocking sheet 100f.
In the 11th example, the imaging lens assembly 5000 further includes a glass panel 5700, which is disposed between the image-side end 5400 and the image surface 5500. The glass panel 5700 can be cover glass, filter or both above, and will not affect a focal length of the imaging lens assembly 5000.
In the imaging lens assembly 5000 according to the 11th example, the parameters of the composite light blocking sheet 100e and the composite light blocking sheet 100f, such as d, t, d/t, ϕ, 1000 t/ϕ, phi D, GU1, GU2, and GU2/GU1, a distance on the central axis Z between the third lens element 5230 and the fourth lens element 5240 is CT1, a distance on the central axis Z between the fourth lens element 5240 and the fifth lens element 5250 is CT2, and the focal length of the imaging lens assembly 5000 is f. The values of d, t, d/t, ϕ, 1000 t/ϕ, phi D, f, f/phi D, CT1, CT2, CT1/t, CT2/t, GU1, GU2, and GU2/GU1 of the 11th example are listed in Table 11.
TABLE 11
11th Example
f = 3.57 mm
Composite light blocking sheet 100e
d (mm)
0.014
f/phi D
1.566
t (mm)
0.024
CT1 (mm)
0.284
d/t
0.583
CT1/t
11.833
Φ (mm)
4.45
GU1 (%)
0.8
1000 t/Φ
5.393
GU2 (%)
3.8
phi D
2.28
GU2/GU1
4.75
Composite light blocking sheet 100f
d (mm)
0.013
f/phi D
0.932
t (mm)
0.023
CT2 (mm)
0.607
d/t
0.565
CT2/t
26.391
Φ (mm)
5.45
GU1 (%)
0.9
1000 t/Φ
4.22
GU2 (%)
6.8
phi D
3.83
GU2/GU1
7.56
Specifically, the imaging lens assembly 6000 further includes an object-side end 6300, an image-side end 6400, and an image surface 6500. The object-side end 6300 faces an imaged object (not shown), and the image-side end 6400 faces the image surface 6500. More specifically, the optical lens set 6200 includes a first lens element 6210, a second lens element 6220, a third lens element 6230, a fourth lens element 6240, a fifth lens element 6250, and a sixth lens element 6260.
The composite light blocking sheet 100g is disposed between the second lens element 6220 and the third lens element 6230, and the composite light blocking sheet 100h is disposed between the third lens element 6230 and the fourth lens element 6240. A spacing element 6610 is disposed between the first lens element 6210 and the second lens element 6220. A spacing element 6620 is disposed between the fourth lens element 6240 and the fifth lens element 6250. A spacing element 6630 is disposed between the fifth lens element 6250 and the sixth lens element 6260.
The first outer surface 112g of the first surface layer 110g of the composite light blocking sheet 100g faces towards the object-side end 6300 of the imaging lens assembly 6000. The first outer surface 112h of the first surface layer 110h of the composite light blocking sheet 100h also faces towards the object-side end 6300 of the imaging lens assembly 6000. Therefore, the reflection of the stray lights can be reduced by correcting assembling the composite light blocking sheet 100g and the composite light blocking sheet 100h.
In addition, as shown in a partial enlarged diagram of
In the imaging lens assembly 6000 according to the 12th example, the parameters of the composite light blocking sheet 100g and the composite light 5i blocking sheet 100h, such as d, t, d/t, ϕ, 1000 t/ϕ, phi D, GU1, GU2, and GU2/GU1, a distance on the central axis Z between the second lens element 6220 and the third lens element 6230 is CT1, a distance on the central axis Z between the third lens element 6230 and the fourth lens element 6240 is CT2, and a focal length of the imaging lens assembly 6000 is f. The values of d, t, d/t, ϕ, 1000 t/ϕ, phi D, f, f/phi D, CT1, CT2, CT1/t, CT2/t, GU1, GU2, and GU2/GU1 of the 12th example are listed in Table 12.
TABLE 12
12th Example
f = 3.954 mm
Composite light blocking sheet 100g
d (mm)
0.006
f/phi D
2.356
t (mm)
0.016
CT1 (mm)
0.351
d/t
0.375
CT1/t
21.938
Φ (mm)
3.25
GU1 (%)
0.3
1000 t/Φ
4.923
GU2 (%)
3.2
phi D
1.7
GU2/GU1
10.67
Composite light blocking sheet 100h
d (mm)
0.028
f/phi D
1.582
t (mm)
0.037
CT2 (mm)
0.157
d/t
0.757
CT2/t
4.243
Φ (mm)
3.55
GU1 (%)
0.7
1000 t/Φ
10.423
GU2 (%)
3.4
phi D
2.5
GU2/GU1
4.86
The imaging lens assembly 4000 further includes the object-side end 4300, the image-side end 4400, and the image surface 4500. The object-side end 4300 faces the imaged object (not shown), and the image-side end 4400 faces the image surface 4500. Moreover, an image sensor 7100 is disposed on the image surface 4500 of the imaging lens assembly 4000.
In particular, the optical lens set 4200 includes the first lens element 4210, the second lens element 4220, the third lens element 4230, the fourth lens element 4240, and the fifth lens element 4250. More particularly, the composite light blocking sheet 100c is disposed between the first lens element 4210 and the second lens element 4220, and the composite light blocking sheet 100d is disposed between the fourth lens element 4240 and the fifth lens element 4250. The spacing element 4610 is disposed between the second lens element 4220 and the third lens element 4230. The spacing element 4620 is disposed between the fourth lens element 4240 and the fifth lens element 4250.
The first outer surface 112c of the first surface layer 110c of the composite light blocking sheet 100c faces towards the object-side end 4300 of the imaging lens assembly 4000. The first outer surface 112d of the first surface layer 110d of the composite light blocking sheet 100d also faces towards the object-side end 4300 of the imaging lens assembly 4000. Therefore, the reflection of the stray lights can be reduced by correcting assembling the composite light blocking sheet 100c and the composite light blocking sheet 100d.
In addition, the composite light blocking sheet 100c is the aperture stop of the imaging lens assembly 4000. Therefore, the structure of the imaging lens assembly 4000 can be simplified. Moreover, the imaging lens assembly 4000 further includes the glass panel 4700, which is disposed between the image-side end 4400 and the image surface 4500. The glass panel 4700 can be cover glass, filter or both above, and will not affect the focal length of the imaging lens assembly 4000.
The parameters and the corresponding values of the composite light blocking sheet 100c and the composite light blocking sheet 100d, such as d, t, d/t, ϕ, 1000 t/ϕ, phi D, GU1, GU2, and GU2/GU1, the distance on the central axis Z (CT1) between the first lens element 4210 and the second lens element 4220, the distance on the central axis Z (CT2) between the fourth lens element 4240 and the fifth lens element 4250, and the focal length (f) of the imaging lens assembly 4000 are referred to Table 10. Thus, there is no further description herein.
The driving assembly 12 can be an auto-focus module, and a driving method thereof can use a voice coil motor (VCM), a micro electro-mechanical system (MEMS), a piezoelectric system or a shape memory alloy system. The driving assembly 12 enables the imaging lens assembly 11 to obtain a preferable imaging position, so that the imaged object in different object distances can be imaged clearly. Moreover, the driving assembly 12 can be coordinated with a kinetic energy sensing element, such as an accelerator, a gyro or a Hall effect sensor. By adjusting the changes in different axial directions of the optical lens set, the blurry image resulting in the shaking of the shooting moment can be compensated, so that the image quality of dynamic scenes or low-light scenes can be enhanced. For example, an optical Image stabilization (OIS) or an electronic image stabilization (EIS) can be featured with the driving assembly 12. Moreover, the image sensor 13 of the image capturing device 10 disposed on the image surface of the imaging lens assembly 11 can have the properties of high light sensitivity and low noise (such as CMOS and CCD), so that the excellent image quality of the imaging lens assembly 11 can be truly presented.
In practical, the image capturing device 10 can be connected with other modules, such as a flash module (not shown herein) or an auxiliary focusing module (not shown herein) for giving the image capturing device 10 required functions. Moreover, the image capturing device 10 can be connected with only one module or can be connected with a plurality of modules. The conductor circuit 14 can be but is not limited to a flexible printing circuit (FPC).
In particular, the two image capturing devices 10 are electrically connected with the flash module 32, the auxiliary focusing module 33, and the image signal processor 34. When a user shoots with the electronic device 30 via an user interface, which is not shown herein but similar to the user interface 25 as shown in
The foregoing description, for purpose of explanation, has been described with reference to specific embodiments and examples. It is to be noted that the foregoing Tables show different data of the different examples; however, the data of the different examples are obtained from experiments. The examples were chosen and described in order to best explain the principles of the disclosure and its practical applications, to thereby enable others skilled in the art to best utilize the disclosure and various examples with various modifications as are suited to the particular use contemplated. The examples depicted above and the appended drawings are exemplary and are not intended to be exhaustive or to limit the scope of the present disclosure to the precise forms disclosed. Many modifications and variations are possible in view of the above teachings.
Chou, Ming-Ta, Lin, Cheng-Feng
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